Acid Rain why it is a concern Issued March 2004 EPA 089/04: This document replaces the EPA Information Sheet No. 22, Acid Rain (January 2001). It eplains what acid rain is and the adverse affects it has upon humans and the environment, and provides information on how acid rain can be reduced. Introduction Australia has not eperienced the problems caused by acid rain in other countries around the world. The emissions produced in this country are, in a global contet, relatively small, and our geographical position isolates us from pollution caused by others. However, being aware of the risks and keeping polluting emissions to a minimum now will help to ensure that acid rain does not become a concern for Australia and South Australia in the future. Pure rainwater is normally acidic, partly because carbon dioide in the atmosphere is dissolved in it. The level of acidity is measured by ph 1 and normally, pure rainwater has a ph of 5.3. Other particles in the atmosphere such as pollutants can lower the acidity level of rain so that it falls below the generally acceptable level of between 5 and 6 and then the rainwater is referred to as acid rain. What is affected by acid rain? Acid rain or acid deposition as it is correctly called not only has an adverse effect on environmental ecosystems, but also affects human health and many of the materials, such as building stone and tetiles, that we use in our daily lives. 1 ph: The potential hydrogen, or ph, scale is used to describe acidity and ranges from 1 (most acidic) to 14 (most basic), with a ph of 7 being neutral.
Ecosystems Acid rain has had major ecological consequences in other parts of the world. Some lakes in countries such as Sweden have become so acidic, from acid rain resulting from pollution in other countries, that they are no longer able to support fish life. Acid rain also has the potential to affect tree and plant life by direct contact with the plants, and also by modifying the acidity of soils for eample, mobilising toic aluminium in the soil. Different soils react differently to acid rain depending on their buffering ability, which is their ability to withstand large changes in ph. For eample, soils covering granite will be affected more than soils covering limestone. Health Nitrogen oides and sulphur dioide in acid rain have been linked with various health problems particularly eye irritations, and lung disorders such as asthma and bronchitis. These effects can be compounded by the presence of other irritants, such as smoke and aerosols. Nitrogen oides are also a major contributor to the formation of ozone in the lower atmosphere, which can also have detrimental health effects on human beings (see EPA 90/04 Photochemical smog). Another obvious health consideration is the indirect effect on resources such as food and water, which can become contaminated. Materials Acid rain can have varying and damaging effects on many different materials (see table below). The damage done, for eample, to ancient stone buildings is irreversible and hence damages the cultural environment of an area. A further consideration is the cost of replacement and repair of many structures and objects that are still in use today. The effects on various materials of acid deposition (source: McCormick 1997) Material Effect Principal air Other factors pollutants Metals Corrosion, tarnishing SO, acid gases Moisture, air, particles, salt Building stone Surface erosion, soiling, black crust SO, acid gases Mechanical erosion, salt, particles, moisture, CO 2, formation temperature, vibration, micro-organisms Paints Surface erosion, discolouration, SO, H 2 S Moisture, ozone, sunlight, particles, mechanical soiling erosion, micro-organisms Paper Embrittlement, discolouration SO Moisture, Photographic Small blemishes SO Moisture, materials Tetiles Soiling, reduced tensile strength SO, NO Moisture, physical wear, acid used in manufacture particles particles, light, physical wear, washing Paints Surface erosion, discolouration, SO, H 2 S Moisture, ozone, sunlight, particles, mechanical soiling erosion, micro-organisms Leather Weakening, powdered surface SO Physical wear, residual acids used in manufacture Rubber Cracking Ozone, sunlight, physical wear page 2
What is in acid rain? The major contributors, called precursors, to acid rain are the common air pollutants: sulphur dioide (SO 2) and the nitrogen oides (NO X) nitric oide (NO) and nitrogen dioide (NO 2). Through a variety of chemical reactions, shown below, these gases form sulphuric acid and nitric acid, which are the two acids responsible for acid rain. How is acid produced? Nitric oide can react with oygen (O 2) to form nitrogen dioide, which can be broken down again by sunlight (hυ) to give nitric oide and an oygen radical (O): 2NO + O 2 2NO 2 NO 2 + hυ NO + O This oygen radical then enables the formation of ozone (O 3): O + O 2 O 3 The presence of ozone causes the formation of more nitrogen dioide by its reaction with nitric oide: NO + O 3 NO 2 + O 2 Or the oygen radical reacts with water to give the hydroyl radical (OH): O + H 2O 2OH This radical then reacts with nitric oide to give nitrous acid (HNO 2) and nitrogen dioide to give nitric acid (HNO 3). It also combines with sulphur dioide (SO 2) to produce sulphuric acid (H 2SO 4): HO + NO HNO 2 NO 2 + HO HNO 3 SO 2 + 2HO H 2SO 4 Where do the precursors come from? While nitric oide and sulphur dioide are produced biogenically (in nature), there are major anthropogenic (man-made) sources of both these polluting gases. Sometimes, natural production of the gases is much higher than human production, but these natural emissions tend to be spread over large areas, dispersing their effects, while the man-made emissions are concentrated around the source of their production. Biogenic sources In nature, bushfires, volcanic eruptions and the decay of organic matter produce significant amounts of sulphur dioide. Nitrogen oides are also generated by bushfires as well as by microbial processes (in soil) and lightning discharges. page 3
Anthropogenic sources Nitrogen oides are produced mainly from the burning of fossil fuels, such as petrol in cars and from power stations burning coal. Sulphur dioide is formed primarily in the burning of (sulphurcontaining) coal and fossil fuels, and in metal smelters. In Adelaide in 2000, an estimated 66% of nitrogen oides (including NO and NO 2) came from motor vehicles, with a further 20% from fuel combustion. Petroleum refinery processing produced 40% of the sulphur dioide emitted to the atmosphere, with motor vehicles contributing 22% and fuel combustion 15%. How are the acids deposited? Acidic pollutants are deposited on the ground either in a wet form through rain, fog or snow, or as dry matter, such as gases or particulates, falling directly from the atmosphere to the ground. The term acid deposition describes all these possibilities and therefore is generally preferred to acid rain. Environmental problems from dry deposition tend to occur closer to the source of the pollution, but wet deposition can occur up to hundreds of kilometres away, in a different region or country, because microscopic aerosol droplets can be carried in clouds. Diagram of the acid deposition process (reproduced with permission from New Scientist Inside Science RBI: 5 November 1987. http://www.newscientist.com) How we can reduce acid rain The most effective way to reduce the incidence of acid deposition is to reduce the emission of its causes the precursors, nitrogen oides and sulphur dioide. Nitrogen oide reduction The main method of lowering the levels of nitrogen oides is by a process called catalytic reduction, which is used in industry and in motor vehicles. For eample, a catalytic converter fitted to a car s ehaust system will convert much of the nitric oide from the engine ehaust gases to nitrogen and oygen. In Australia, all motor vehicles built after 1985 must be fitted with catalytic converters. page 4
Nitrogen is not in the actual fuels used in motor vehicles or power stations; it is introduced from the air when combustion occurs. Using less air in combustion can reduce emissions of nitrogen oides. Temperature also has an effect on emissions the lower the temperature of combustion, the lower the production of nitrogen oides. Temperatures can be lowered by using processes such as twostage combustion and flue gas recirculation, water injection, or by modifying the design of the burner. Sulphur dioide reduction There are several methods to lower the sulphur dioide emissions from coal-fired power stations. These include simple methods of prevention, such as using coal with a low sulphur content and physical coal cleaning. However, where sulphur dioide eists in greater quantities, more comple methods are needed to reduce emissions and these can include processes such as flue gas desulphurisation and fluidised bed combustion. Coal sulphur content Most Australian coals have a sulphur content of 0.1 1%, which is quite low by world standards. Traditionally, black coal, with a sulphur content of approimately 1%, has predominantly been used in Australia. Leigh Creek coal, mined in South Australia, is a lignite A coal with a sulphur content of 0.4%. Physical coal cleaning Coal can be cleaned because sulphur in coal is often in the form of mineral impurities, such as pyrites, and these can be separated from the coal. The more finely coal is crushed before use, the more impurities such as sulphur that are removed from it. Flue gas desulphurisation Flue gas desulphurisation is based on using limestone to absorb the sulphur dioide (see the equation below) and is one of the most effective methods of removal. However, the process generates solid wastes (calcium sulphates, CaSO 3 and CaSO 4) which require disposal. H 2 O, O 2 CaCO 3 ( limestone) + SO 2 CaSO 3 + CaSO 4 + CO 2 + H 2O Fluidised bed combustion In this process, the coal is crushed and passed into a fluidised bed for combustion. The bed consists of fine particles of an absorbent material such as limestone. Hot air is passed through it and this causes the particles to behave as though they were a fluid (fluidised). The sulphur dioide can then be absorbed by the limestone particles in the bed. Fluidised bed combustion can be operated at lower temperatures and therefore produces less nitrogen oide, but once again, solid waste is created and requires disposal. References Holper, P 1996, Acid Air? Tracking Acidification in Australia and Asia, Atmosphere, Issue 1, February. page 5
Kemp, D 1994, Global environmental issues: A climatological approach, 2nd ed., Routledge, London. Fred Pearce 1987, Inside Science: Acid Rain, New Scientist, 5 November. White, V 1998, Air emissions inventory for the Adelaide airshed 1995, Environment Protection Agency, South Australia. McCormick, J 1997, Acid earth: The politics of acid pollution, Earthscan, London. Horseman, D & Carnovale, F 1989, Acid rain in Australia: A national assessment, Australian Environment Council, Report No. 25, Australian Government Publishing Service, Canberra. FURTHER INFORMATION Legislation Legislation may be viewed on the Internet at: www.parliament.sa.gov.au/dbsearch/legsearch.htm Copies of legislation are available for purchase from: Government Information Centre Telephone: 13 23 24 Lands Titles Office, 101 Grenfell Street Internet: shop.service.sa.gov.au Adelaide SA 5000 For general information please contact: Environment Protection Authority Telephone: (08) 8204 2004 GPO Bo 2607 Facsimile: (08) 8204 9393 Adelaide SA 5001 Freecall (country): 1800 623 445 E-mail: epainfo@epa.sa.gov.au Internet: www.epa.sa.gov.au page 6